Substantia. An International Journal of the History of Chemistry 4(2) Suppl.: 89-94, 2020

Firenze University Press 
www.fupress.com/substantia

ISSN 2532-3997 (online) | DOI: 10.36253/Substantia-841

Citation: M. Ziaee, M. Taseidifar, R.M. 
Pashley, B.W. Ninham (2020) Efficient 
Dewatering of Slimes and Sludges with 
a Bubble Column Evaporator. Substan-
tia 4(2) Suppl.: 89-94. doi: 10.36253/
Substantia-841

Copyright: © 2020 M. Ziaee, M. Taseidi-
far, R.M. Pashley, B.W. Ninham. This is 
an open access, peer-reviewed article 
published by Firenze University Press 
(http://www.fupress.com/substantia) 
and distributed under the terms of the 
Creative Commons Attribution License, 
which permits unrestricted use, distri-
bution, and reproduction in any medi-
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source are credited.

Data Availability Statement: All rel-
evant data are within the paper and its 
Supporting Information files.

Competing Interests: The Author(s) 
declare(s) no conflict of interest.

Efficient Dewatering of Slimes and Sludges with 
a Bubble Column Evaporator

Mohammad Ziaee1, Mojtaba Taseidifar1, Richard M. Pashley1,*, Barry 
W. Ninham2

1 School of Science, UNSW Canberra, Northcott Drive, Canberra, Australia
2 Department of Applied Mathematics, Research School of Physical Sciences and Engi-
neering, Australian National University, Canberra, Australia
*Corresponding author: r.pashley@adfa.edu.au

Abstract. The recalcitrant nightmare of de-watering slime/sludge is a major issue, 
for both industry and the environment. A simple process is developed that solves the 
problem. It uses a bubble column evaporator (BCE) with heated dry air. The model 
slime to illustrate the de-watering process was a concentrated dispersion of spherical 
5 micron silica particles in pure water. Typical slime samples were de-watered in the 
range 20-35% colloid/water (w/w) using dry inlet gases pre-heated to temperatures of 
150 °C and 250 °C. The BCE process was run at sub-boiling temperatures, with the 
column solution in the range, 43 and 74 °C, with those two inlet temperatures operat-
ing for de-watering the slime. A significant bonus is that the pure water vapour pro-
duced can be condensed and used as a source of high-quality water for reuse. The BCE 
process offers simplicity, resilience to slime feed quality, and a pure water biproduct. 
It also offers a continuous and controlled low-maintenance process. These are clear 
advantages in de-watering a wide variety of industrial slimes and sludges. In addition, 
the process involves the passage of a continuous flow of hot dry gases. This causes the 
dispersion to remain sufficiently fluid to allow easy transportation. However, once the 
hot gas flow ceased, the dispersion immediately solidified. The success of the bub-
ble column process for dewatering and validation of the mechanism is even more 
enhanced if helium is used instead of air. It appears that hot helium atoms can disrupt 
water hydrogen-bonding in the liquid surrounding the hot bubbles and this enhanc-
es water vapour collection efficiency. The bubble method appears to offer more than 
significant advantages over other methods, such as hydrocyclone methods, which are 
often used to de-water mining wastes.

Keywords: slime and sludge de-watering, bubble column evaporator, silica spheres, 
helium gas.

1. INTRODUCTION – SLIME AND SLUDGE DE-WATERING 

The words sludge or slime are used to mean a high water-content col-
loidal dispersion that stubbornly resists de-watering. De-watering is a pro-
cess in which water is separated from the solids, to thicken up the waste 
for disposal or end-user purposes. This is a problem that poses major eco-



90 Mohammad Ziaee, Mojtaba Taseidifar, Richard M. Pashley, Barry W. Ninham

nomic, environmental and safety challenges for a range 
of sludge types in industries like clay production, phos-
phate mining, diamond mining, sewage sludges, sand 
washing, and sludges from paper mills, gold mining, and 
different metallic ores. As an example, phosphate min-
ing produces clay tailing slurries or sludges which are 
usually less than 10% solid content. This must be de-
watered to a value of at least 40% by an economically 
acceptable process. Often the solid content has an aver-
age particle size equal to or less than 50 microns. This 
is generally characteristic of suspensions of siliceous 
and clay solids, and for other minerals, depending on 
the industrial process.1,2 Different techniques to de-
water sludges are employed in different industries. They 
include coagulation, f locculation, grinding, heating, 
applying high voltages and using hydrocyclones. How-
ever, each of these techniques has its own drawbacks and 
they often fail to provide desirable solid content levels. 
For instance, flocculation and coagulation methods need 
considerable amounts of chemical agents which might 
cause environmental, economic and safety concerns.2,3

Conventional methods, for example ponding, also 
suffer from disadvantages. It is time consuming and 
requires large acreages of land to effectively de-water 
large volumes of slurries. This also increases land main-
tenance and remediation costs, also causes environmen-
tal and health issues.2 Hydrocyclones are frequently used 
in different industries for de-watering of solid-liquid 
suspensions. Generally, large hydrocyclones are used for 
separation of particles (larger than 25 µm) from slimes, 
while smaller hydrocyclones with diameters less than 
10mm are usually used to separate fine particles smaller 
than 10 µm.

The controllability and efficiency of the hydrocy-
clone method are limited and this method needs to be 
augmented by further processes like centrifugation to 
optimise dewatering.4 Hydrocyclones, in general, are 
comprised of an inlet, a main body and two outlets. In 
order to increase the recovery of solids, the feed pres-
sure needs to be increased. Other conditions such as 
relationship between cutsize, bypass and water recov-
ery determine the performance. Thus, depending on the 
waste type, they need to be optimised in order to obtain 
maximum efficiency in de-watering.5,6 Also, for further 
improvement of the hydrocyclone process, a centrifuge 
can also be incorporated. This uses centrifugal forces 
made by spinning a bowl or basket to separate the sludge 
solids from the liquid.7

In this work a novel method of de-watering slime 
using a bubble column evaporator (BCE) is developed 
and evaluated. This can be used for many different 
sludge thickening applications. The BCE exploits the 

high interfacial area between gas bubbles and water and 
acts as a natural semi-permeable membrane. This pro-
cess uses hot bubbles to allow water vapour to escape 
but not the solid particles. So far, a wide range of use-
ful applications of the BCE process have been developed 
by our research group. The list includes: a new method 
for the precise measurement of enthalpies of vaporisa-
tion (ΔHvap) of concentrated salt solutions;8,9 evaporative 
cooling;10 a new method for thermal desalination11-13 a 
novel method for sub-boiling thermal sterilization;9,14-18 
a novel method for the low-temperature thermal decom-
position of some solutes in aqueous solution;19 and a new 
approach to aqueous solute precipitation in a controlled 
manner.20 In addition, a bubble column condenser has 
also been designed for the production of high- qual-
ity water as condensate.21-23 Figure 1 depicts the various 
applications of the BCE technique we have developed. 
The green arrows refer to the previous applications 
developed by the BCE method, while the red arrow refer 
to the latest application of this method.

2. MATERIALS AND METHODS

For each experiment 50 g of 5 µm spherical silica 
powder supplied by US Research Nanomaterials Com-
pany was used. Milli-Q water was added to pure 50 g 
of silica powder to reach 250 g of water-silica mixture. 
Then, the mixtures were stirred to produce uniform dis-
persions. The measured turbidity of silica mixtures (20% 

Figure 1. Different applications for the BCE process.



91Efficient Dewatering of Slimes and Sludges with a Bubble Column Evaporator

weight), was about 40,000 NTU measured by HACH 
2100AN Turbidimeter. The concentration of solid par-
ticles (slime thickness) in the mixtures were calculated 
using the following formula:

solid concentration % = 
 
× 100 (1)

The BCE process is illustrated schematically in Fig-
ure 2. In this work, four experiments were undertaken 
for de-watering the prepared slime samples using two 
different gases (dry air, helium) at two different outlet 
gas temperatures (150 °C, 250 °C). 

In each experiment, 250 mL of the prepared slime 
sample was poured into a 120 mm diameter open-top 
glass column (Büchner type, Pyrex® Borosilicate, VWR) 
with a sinter porosity of number 2. The outlet gas tem-
perature was varied using a Tempco air heater (300W) 
with a thermocouple temperature monitor and an AC 
Variac electrical supply. A TENMARS thermometer 
(TM-84N, Taiwan) with the accuracy of ± 1.5 °C was 
applied on the surface of the sinter to measure the tem-
perature of hot gas introduced to the empty column.

The air gas was produced from an air pump (Hiblow 
HP40, Philippines) and a BOC gas flow meter was used 
to measure flow rates. The temperature of the column 
solution was also continuously monitored using a ther-
mocouple positioned at the centre of the aqueous mix-
tures. Due to our requirement of a slime gas temperature 
up to 250 °C, the temperature of the gas heater might 
reach above 700 °C. That necessitates the use of a steel 
heater and brass connectors for the downstream, and the 
use of Rockwool as an insulating material.

The effectiveness of the BCE process was quanti-
fied experimentally based on the weight loss of the slime 
using the following equation: 

water loss % = 
 
× 100 (2)

where W1, W2, and Wd are the initial weight of slime, 
final weight of slime, and the weight of dry solid com-
pounds, respectively

3. RESULTS AND DISCUSSION

3.1. Results for Air

In the first experiment, 250 g of a silica-water mix-
ture with a concentration of 20% was poured to the col-
umn using hot dry air at a temperature of 150 °C. After 
45 minutes using hot air with a flow rate of 34 (L/min) 
for production of hot bubbles in the aqueous mixture, 
the residual mixture was weighed and the new solid con-
centration (slime thickness) was calculated using equa-
tion (1). The results are presented in Table 1. It shows 
that the final solid concentration (slime thickness) is 
30.5%. Also, the density of the dispersion was increased 
in this process from 1.05 g/mL to 1.16 g/mL and the 
operating temperature of the BCE slime remained at 
about 48-49 °C.

In the second experiment applying dry air at the 
temperature of 250 °C with a flow rate of 34 L/min over 
45minutes, the silica concentration increased from 20 to 
34.7%. The temperature of the slime mixture remained 
in the range of 65-66 °C. The density increased from 
an initial value of 1.05 to 1.25 g/mL. An example of the 
bubbling process is shown in the photograph in Figure 3.

3.2. Results for Helium

When helium gas was used for producing bubbles, 
the helium flow rates were measured using two methods: 
by weighing the helium cylinder and from calculations 
based on the helium cylinder pressure differential. The 
first method gave a flow rate of about 13.9 L/min and 
the calculations based on the helium cylinder pressure 
differential led to a flow rate of 10.4 L/min. Therefore, 
an average value of 12 L/min was used for comparison 
with the 34 L/min dry air flow. According to the previ-
ous studies, helium is a more effective gas in bubbling 
because of its natural production of smaller bubbles, 
even in pure water.13

In these experiments helium flowed into the BCE 
column containing 20% silica dispersion at an inlet tem-
perature of 150 °C, flow rate of 12 L/min. After 45 min 
with the column solution equilibrating at about 41 °C, 
the silica concentration was increased to 28% and the 

Figure 2. Schematic diagram of BCE system for slimes de-watering.



92 Mohammad Ziaee, Mojtaba Taseidifar, Richard M. Pashley, Barry W. Ninham

solution density increased from 1.05 g/mL to 1.19 g/mL. 
When the helium inlet gas temperature was increased to 
250 °C at 12 L/min, after 45 min with the column solu-
tion equilibrating at about 63°C, the silica concentra-
tion (slime thickness) was increased to 32.5% and the 
solution density increased from 1.05 g/mL to 1.23 g/mL. 
Table 1 summarises the de-watering results of 20% silica 
slimes using BCE process with air and helium gases.

At these high silica content levels, the dispersion 
remained sufficiently fluid for reasonable transport but 
on stopping the hot inlet gas flow the dispersion imme-
diately solidified. 

The values reported in Table 1 are the mean values 
calculated based on the data obtained after three runs for 
each single experiment. Besides undertaking experiments 
using silica-water slime, four experiments have been car-
ried out using both air and helium (at 150 °C and 250 °C) 
with an industrial slime which had a similar compound 
composition. The results achieved were very close to the 
results obtained for de-watering the model silica slime.

Figure 4 shows a Scanning Electron Microscopy 
(SEM) image of the precipitated silica particles used in 
this study. This shows that they are of spherical appear-
ance and very fine.

Fine particles (e.g., silica spheres) can stabilise foams 
even in the absence of surfactants or polymers.25 Aque-

ous foams stabilised solely by particles, but these are 
usually partially hydrophobic and so have an amphi-
philic nature.25 The studies reported here were based on 
the use of hydrophilic silica particles dispersed in pure 
water. These micron sized particles would generally act 
to destabilise foams via water film rupture and hence 
even with continuous air and helium gas flow no signifi-
cant level of transient foaming was observed.

The relative water loss under different conditions is 
calculated based on equation (2) and summarised in Fig-
ure 5. Regarding the Figure, using helium gas is much 
more effective than dry air since this level of de-watering 
was achieved at about one third of the volumetric flow 
rate compared with air.

In order to compare the efficiency of using different 
gases for slime de-watering the following equation 3 was 
used:

 (3)

Figure 3. Photograph of the BCE process applied to 20% silica 
slimes using hot air.

Table 1. De-watering of initial 20% silica slime (density of 1.05 g/
mL) using BCE process with different gases (air and helium).

Gas Flow 
Rate

(L/min)

Gas Tem-
perature

(°C)

Slime Tem-
perature

(°C)

Slime 
Thickness

(%)

Slime 
Density
(g/mL)

BCE 
with air

34 150 48-49 30.5 1.16
34 250 65-66 34.7 1.25

BCE 
with He

12 150 41 28.0 1.19
12 250 63 32.5 1.23

Figure 4. SEM of micro-silica spheres produced by precipitation.



93Efficient Dewatering of Slimes and Sludges with a Bubble Column Evaporator

where E, Cp, F are efficiency of gas carrier, heat capacity 
of gas at the constant pressure, and gas flow rate, respec-
tively. Also, numbers refer to gas carrier 1 and 2. The 
water loss factor for each gas carrier can be calculated 
from equation (2) and the Cp value for air and helium 
gases are 29.31 and 20.77 (J mole-1 K-1), respectively. The 
EHelium/EAir ratio regarding operational temperatures at 
150 °C and 250 °C, gas flow rates, and water loss are 3.25 
and 3.62 respectively. This means that to reach an equal 
level of slime de-watering, helium almost needs less than 
1/3 of the energy which air needs. 

4. CONCLUSIONS

The BCE system was found to be very effective for 
slime de-watering. This is major step forward. Its effec-
tiveness was found to depend on the gas temperature. 
Heated dry air gas at 250 °C was found to be signifi-
cantly more effective than applying hot dry air at 150 °C 
to concentrate the slime. It was found that helium gas is 
more effective than air. We conjecture that this might be 
due to the very small size of a helium atom with a diam-
eter of 62 pm. Helium atoms can break the hydrogen 
bonding among water molecules adjacent to the gas-liq-
uid interface and allow easier transfer of water molecules 
into the rising helium bubbles. (The length of hydrogen 
bonding among water molecules in the liquid phase is 
about 1.97 Å).

The BCE method using hot, dry carrier gases offers a 
promising technique to de-water a wide variety of slimes 
and slurries produced in different industries. It is simple 
and robust. This process might offer a novel competitive 
dewatering process and could be readily scaled up. It 
offers a robust process which can replace existing tech-

niques such as flocculation, hydrocyclones, and pond-
ing. The BCE technique applied to de-watering also has 
the very significant additional advantage of producing 
high quality water from condensation of the sub-boiling 
water vapour.

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